KR20020023284A - Absorbent Circulation Cooling Unit - Google Patents

Abstract

The present invention is a cooling device using a refrigerant as water (H2O) and an absorbent using lithium bromide (LiBr), by spraying water, which is a refrigerant, into a high vacuum evaporation tank to evaporate at a low temperature, and cooling using latent heat of evaporation. The vaporized refrigerant vapor is absorbed by the absorbent circulating the absorption tank, the refrigerant vapor is discharged to the outside after heat separation from the regeneration tank, and the refrigerant separated from the refrigerant is cooled in the absorbent cooling tank and then transferred to the absorption tank to be evaporated. It is an object of the present invention to provide a high efficiency and low cost absorbent circulation cooling device as a device for absorbing refrigerant vapor than an absorption cooling device of a refrigerant circulation method.

Specific means for achieving the above object is as follows.

When the inside of the evaporation tank connected to the absorption tank is made into a high vacuum of 6.5 mmHg by using a vacuum pump and water is injected into the evaporation tank, water evaporation occurs at a low temperature of 5 ° C inside the evaporation tank. Cooling is performed by heat exchange action with brine circulating through the evaporative latent heat and heat exchange tubes, and the evaporated refrigerant vapor is transferred to the absorption tank, absorbed by the circulating absorbent, and transferred to the regeneration tank, and then transferred to the regeneration tank. The absorbent of the solution is heated to separate the refrigerant vapor and the absorbent of the concentrated solution, and the separated absorbent of the concentrated solution is transferred to the absorbent cooling tank, cooled, and then transferred to the absorption tank to absorb the refrigerant, and the refrigerant vapor separated from the absorbent is stored in the outside air. It is completed by configuring an apparatus for discharging furnace.

The absorbent circulation cooling device according to the present invention comprises a system for circulating the absorbent by using an absorbent circulation device connected to an evaporation tank to discharge the refrigerant vapor heat exchanged with the cooling load to the outside air, thereby providing a high efficiency and low cost cooling device. do.

Description

Absorbent circulating air conditioner

The present invention is a device for performing cooling by circulating the absorbent by using the refrigerant as water (H2O) and the absorbent by using lithium bromide (LiBr), in the cooling device for discharging the refrigerant vapor after cooling to the outside without condensation It is about.

Conventional absorption type cooling device uses refrigerant as water (H2O) and absorber as lithium bromide (LiBr) to cool water through high temperature evaporation, absorption, heat regeneration and cooling condensation in high vacuum. Run Absorption cooling system consists of a refrigerant circulation system that cools the water used for cooling by cooling evaporation, absorption, heating regeneration, and cooling condensation process by using latent heat of evaporation generated from the phase change of water and steam, which is refrigerant. Since the cooling water produced by the separate cooling device must be circulated to the absorber and the condenser to satisfy the required temperature condition of the refrigerant, it is not only a problem that the initial equipment investment due to the installation of the cooling device is excessive, but also to operate the cooling device. There is a problem in that operating costs occur. In addition, since a large amount of water is evaporated using the cooling tower to produce cooling water to supply the cooling water, there is a problem in that water is excessively consumed.

In order to solve the problems of the above absorption type cooling device, the absorbent is circulated in absorption, heat separation, and cooling, the refrigerant is cooled at low temperature in the evaporation tank, the vaporized refrigerant vapor is absorbed in the absorption tank, and then separated by heating in the regeneration tank. Configure the device to be discharged. When the refrigerant, water, is injected into a 6.5 mmHg high vacuum evaporation tank, evaporation occurs at a low temperature of 5 ° C. The refrigerant vapor heat exchanged with the brine circulating in the heat exchange tube of the evaporation tank is transferred to the absorption tank through which the absorbent circulates, and the brine heat-exchanged with the latent heat of evaporation of the water, which is the refrigerant, performs room cooling. The refrigerant vapor transferred to the absorption tank is absorbed by the absorbent of the agricultural solution circulating in the absorption tank and is transferred to the regeneration tank. The regeneration tank heats the absorbent of the rare solution absorbing the refrigerant vapor to separate the refrigerant vapor from the absorbent and the refrigerant vapor. The absorbent of the separated concentrate is transferred to the absorbent cooling tank. The refrigerant vapor separated from the absorbent is discharged to the outside in the form of hot steam. The absorbent transferred to the absorbent cooling tank is configured to be cooled in the absorbent cooling tank and then transferred to the absorption tank to absorb the refrigerant vapor generated in the evaporation tank.

Absorption cooling system in which the refrigerant circulates generates heat of absorption when absorbing the refrigerant vapor generated in the evaporator. If the absorption heat is not cooled, the refrigerant vapor is separated from the absorbent. Should be removed. In addition, in the regenerator, the absorbent absorbing the refrigerant vapor is heated to separate the absorbent and the refrigerant, and to supply condensed water using a separate cooling device to condense the heated refrigerant vapor. Absorption cooling system in which the refrigerant circulates consists of a system that requires cooling energy to condense the refrigerant, supply cooling water to remove the heat of absorption from the absorber, and require heating energy for heating to separate the absorbent from the refrigerant. This is excessive and low energy use efficiency.

Absorbent circulating cooling system is composed of a system that injects the cooled absorbent into the absorption tank to absorb the refrigerant vapor generated in the evaporation tank and heat-separates the absorbent including the absorption heat from the regeneration tank. In addition to separating the absorbents, only the absorbents in which the refrigerant is separated by using the absorbent cooling tank are used for cooling. It is a technical subject to provide.

1 is an evaporation tank system diagram.

2 is a schematic diagram of an evaporative refrigerant separator.

3 is an absorption tank system diagram.

4 is a regeneration tank system diagram.

5 is an absorbent cooling tank system diagram.

6 is a water tank system diagram.

7 is a system diagram of the absorbent circulation cooling device.

<Explanation of symbols for main parts of drawing>

E.T: Evaporation Tank F.T: Flash Steam Separator

A.T: Absorption Tank G.T: Regeneration Tank

A.C.T: Absorbent Cooling Tank W.T: Water Tank

E.T-W: Evaporation Tank Refrigerant A.F.T: Absorbent Filter

E.T-S V / V: Solenoid valve for evaporation tank refrigerant inlet control

E.T-N: Evaporation Tank Refrigerant Injection Nozzle

E.T-P: Evaporation Tank Refrigerant Circulation Pump

E.T-S1: Evaporation Tank Level Detection Sensor (Bottom)

E.T-S2: Evaporation Tank Level Detection Sensor (Upper)

E.T-1L: Evaporation Tank Refrigerant Inlet Pipe

E.T-2L: Evaporation Tank Refrigerant Circulation Tube

E.T-3L: Evaporation Tank Refrigerant Steam Transfer Tube

E.T-4L: Brine Inlet Tube

E.T-5L: Brine Transfer Pipe

E.T-6L: Flashing refrigerant inlet pipe

F.T-C.F: Ceramic Filter for Separation of Flash Steam

F.T-P: Refrigerant Steam Circulation Pump

F.T-1L: Evaporative Refrigerant Separator Refrigerant Steam Inlet Pipe

F.T-2L: Evaporative Refrigerant Separator Refrigerant Steam Transfer Pipe

F.T-3L: Evaporative Refrigerant Separator

A.T-A.N: Absorption Tank Absorbent Injection Nozzle

A.T-E.N: Absorption Tank Refrigerant Steam Injection Nozzle

A.T-P: Absorbent Circulation Pump

A.T-S V / V: Absorption Tank Vacuum Solenoid Valve

A.T-V.P: Absorption Tank Vacuum Pump

A.T-A: Absorption Tank Absorbent

A.T-1L: Absorption Tank Absorbent Inlet Pipe

A.T-2L: Absorption Tank Refrigerant Steam Inlet Pipe

A.T-3L: Absorption Tank Rare Solution Absorbent Transfer Tube

G.T-1: Low Temperature Regeneration Tank

G.T-2: High Temperature Regeneration Tank

G.T-A.N: Regeneration Tank Absorbent Spray Nozzle

G.T-P: Regeneration Tank Absorbent Circulation Pump

G.T-A: Regeneration Tank Absorbent

G.T-1L: Regeneration Tank Rare Solution Absorbent Inlet Pipe

G.T-2L: Regeneration Tank High Temperature Absorbent Inlet Pipe

G.T-3L: Recycle Tank Agricultural Solution Absorbent Transfer Tube

G.T-4L: High Temperature Refrigerant Steam Transfer Tube

G.T-5L: Regeneration Tank High Temperature Refrigerant Steam Discharge Tube

G.T-6L: Boiler High Temperature Steam Inlet Pipe

G.T-7L: Boiler Low Temperature Steam Transfer Tube

A.C.T-A.T: Absorbent Cooling Tank Absorption tank to absorb evaporated refrigerant

A.C.T-A.N: Absorbent Cooling Tank Absorbent Injection Nozzle

A.C.T-W.N: Absorbent Cooling Tank Refrigerant Injection Nozzle

A.C.T-S V / V: Solenoid Cooling Tank Refrigerant Intake Control Solenoid Valve

A.C.T-P: Absorbent Cooling Tank Refrigerant Circulation Pump

A.C.T-S1: Absorbent Cooling Tank Refrigerant Level Detection Sensor (Bottom)

A.C.T-S2: Absorbent Cooling Tank Refrigerant Level Detection Sensor (Top)

A.C.T-W: Absorbent Cooling Tank Refrigerant

A.C.T-A: Absorbent Cooling Tank Absorbent

A.C.T-V. S V / V: Absorbent cooling tank vacuum control solenoid valve

A.C.T-V.P: Absorbent Cooling Tank Vacuum Pump

A.C.T-1L: Absorbent Cooling Tank Absorbent Inlet Pipe

A.C.T-2L: Absorbent Cooling Tank Cooling Absorbent Transfer Tube

A.C.T-3L: Absorbent Cooling Tank Refrigerant Inlet Tube

A.C.T-4L: Absorbent Cooling Tank Refrigerant Circulation Tube

A.C.T-5L: Absorbent Cooling Tank Rare Solution Absorbent Transfer Tube

A.C.T-6L: Absorbent Cooling Tank Vacuum Generator Tube

W.T- S V / V: Water Tank Refrigerant Inlet Control Solenoid Valve

W.T-S1: Water Tank Refrigerant Level Detection Sensor (Bottom)

W.T-S2: Water Tank Refrigerant Level Detection Sensor (Upper)

W.T-W: Water Tank Refrigerant

W.T-F: Water Tank Refrigerant Filter

W.T-1L: Cold Water Inlet Pipe

W.T-2L: Waterworks Inlet Pipe

W.T-3L: Water Tank Refrigerant Transfer Pipe

1 is an evaporation tank (E.T) system diagram.

2 is a schematic diagram of a flash evaporative refrigerant separator (F.T).

3 is an absorption tank (A.T) system diagram.

4 is a regeneration tank (G.T) system diagram.

5 is a system diagram of an absorbent cooling tank (A.C.T).

6 is a water tank (W.T) system diagram.

7 is a system diagram of the absorbent circulation cooling device.

Description of the absorbent circulation cooling device system diagram of Figure 7 is as follows.

Absorbent circulating cooling device uses refrigerant (H2O) as refrigerant and lithium bromide (LiBr) as an absorbent. It is cooled by heat exchange with brine containing latent heat and cooling load generated by evaporation of water as refrigerant. Evaporation tank (ET) to be executed, refrigerant separator (FT) not evaporated, absorption tank (AT) to absorb refrigerant vapor, regeneration tank (GT) to heat-separate absorbent and refrigerant, and absorbent to cool down absorbent separated from refrigerant It consists of a cooling tank ACT and the water tank WT which stores the water which is a refrigerant.

The configuration and operation of the main components are described in detail as follows.

1 is an evaporation tank (E.T) system diagram.

The configuration of the evaporation tank (ET) includes a circulation pump (ET-P) for circulating heat exchange tubes (ET-4L, ET-5L) and a refrigerant (ET-W) for performing heat exchange between the latent heat of evaporation and the cooling load, Upper and lower water level detection sensors (ET-S1, ET-S2) for detecting the water level of the refrigerant (ET-W), inlet pipe (ET-1L) for introducing the water of the refrigerant (ET-W) from the water tank (WT), The solenoid valve (ET-SV / V) installed in the inlet pipe (ET-1L) to adjust the amount of refrigerant (ET-W) drawn in according to the signals of the sensors (ET-S1, ET-S2), and evaporated It consists of a refrigerant | coolant vapor conveyance pipe (ET-3L) which conveys refrigerant | coolant vapor | steam. And a refrigerant circulation pipe (E.T-2L) for circulating the refrigerant (E.T-W) and a refrigerant inlet pipe (E.T-6L) separated from the evaporative refrigerant separator (F.T).

The operation of the evaporation tank (E.T) configured as described above is as follows.

When the vacuum pump (AT-VP) installed in the absorption tank (AT) connected to the evaporation tank (ET) is operated and the inside of the evaporation tank (ET) becomes a high vacuum state of 6.5 mmHg, the electrons installed in the refrigerant inlet pipe (ET-1L) The valve (ET-SV / V) is opened and the refrigerant water is drawn in from the water tank (WT) to move the refrigerant spray nozzle (ET-N) over the evaporation tank (ET) heat exchange tubes (ET-4L, ET-5L). Sprayed through. The injected refrigerant E.T-W evaporates at a low temperature of 5 ° C. under a high vacuum of 6.5 mmHg. Evaporative latent heat generated by evaporation of refrigerant (ET-W) and brine circulating in the evaporation tank (ET) heat exchange tubes (ET-4L, ET-5L) and brine cooled by the heat exchange action are cooled while circulating to the indoor unit. Is executed. The evaporated refrigerant vapor is transferred to the absorption tank (AT) through the refrigerant vapor transfer pipe (ET-3L) and absorbed by the cooled agricultural solution absorbent, so the inside of the evaporation tank (ET) maintains a high vacuum of 6.5 mmHg at 5 ° C. The low temperature evaporation effect of The non-evaporated refrigerant (ET-W) is separated by the evaporative refrigerant separator (FT) and transferred to the evaporation tank (ET) through the evaporative refrigerant inlet pipe (ET-6L) to the refrigerant circulation pump (ET-P). Circulated by the spray. As the refrigerant ET-W introduced from the water tank WT is evaporated by the evaporation action and the refrigerant vapor is transferred to the absorption tank AT, the refrigerant ET-W inside the evaporation tank ET is reduced to detect the lower water level. When the amount of the refrigerant ET-W is detected by the sensor ET-S1, the solenoid valve ET-SV / V is opened by the signal of the sensor ET-S1, and the refrigerant ET from the water tank WT. -W) water is drawn in and the level of the coolant ET-W rises and the amount of the coolant ET-W is detected by the upper water level sensor ET-S2. The solenoid valve ET-SV / V is closed to repeat the process of stopping the refrigerant ET-W and adjusts the level of the refrigerant ET-W in the evaporation tank ET.

The main function of the evaporation tank (E.T) is to continuously evaporate the refrigerant (E.T-W) and to use the latent heat of evaporation to perform continuous cooling by the heat exchange action with the cooling load.

2 is a schematic diagram of an evaporative refrigerant separator (F.T).

The evaporative refrigerant separator (FT) includes a refrigerant vapor inlet pipe (FT-1L), a porous ceramic filter (FT-CF), an evaporative refrigerant feed pipe (FT-3L), a steam refrigerant feed pipe (FT-2L), and It consists of a refrigerant vapor circulation pump (FT-P).

Referring to the operation of the non-evaporative refrigerant separator (F.T) configured as described above are as follows.

The refrigerant vapor evaporated at a low temperature in the evaporation tank (ET) is introduced into the evaporative refrigerant separator (FT) by the refrigerant vapor circulation pump (FT-P) and passes through the porous ceramic filter (FT-CF) in which fine pores are formed. It is transferred to the absorption tank AT through the transfer pipe FT-2L. As the refrigerant vapor passes through the porous ceramic filter (F.T-C.F), the moisture that is not evaporated is raised in the ceramic filter (F.T-C.F) and transferred to the evaporation tank (E.T) through the evaporative refrigerant transfer pipe (F.T-3L).

The main function of the non-evaporative refrigerant separator (F.T) is to increase the efficiency of absorption and heat separation and to reduce the amount of refrigerant vapor discharged to the outside by filtering out moisture that is not evaporated.

3 is a system diagram of the absorption tank A.T.

The structure of the absorption tank AT includes the refrigerant vapor inlet pipe (AT-2L), the agricultural solution absorber inlet pipe (AT-1L), the rare solution absorbent feed pipe (AT-3L), the absorbent circulation pump (AT-P), and It consists of a vacuum pump (AT-VP) which makes the evaporation tank (ET) and the absorption tank (AT) inside into a vacuum state.

Referring to the action of the absorption tank (A.T) configured as described above are as follows.

The refrigerant vapor which has passed through the vaporization refrigerant separator (FT) by the refrigerant vapor circulation pump (FT-P) is introduced into the absorption tank (AT) through the refrigerant vapor inlet pipe (AT-2L), and the refrigerant vapor injection nozzle (AT- When the absorbent of the agricultural liquid cooled by EN) and cooled in the absorbent cooling tank ACT is introduced through the absorbent inlet pipe AT-1L and sprayed by the absorbent injection nozzle AT-AN, the refrigerant vapor is absorbed. Absorbent of the rare solution absorbed by the absorber and collected in the lower part of the absorption tank (AT) and absorbing the refrigerant vapor is transferred to the regeneration tank (GT) by the absorbent circulation pump (AT-P) through the rare solution absorbent transfer pipe (AT-3L). Transferred.

The main action of the absorption tank A.T is to carry out the action of the absorbent of the cooled concentrated solution absorbing the refrigerant vapor and transferring the absorbent of the rare solution absorbing the refrigerant vapor to the regeneration tank G.T.

4 is a regeneration tank (G.T) system diagram.

The regeneration tank GT includes a rare-solution absorbent inlet tube (GT-1L) that absorbs refrigerant vapor, a concentrated-solution absorber transfer tube (GT-3L) separated from the refrigerant vapor, and a refrigerant discharge tube (150) for discharging the separated refrigerant to the outside air ( GT-5L), a low temperature regeneration tank (GT-1) and a high temperature regeneration tank (GT-2) for separating and separating a rare solution absorbent.

Referring to the operation of the regeneration tank (G.T) configured as described above are as follows.

Absorbent of the rare solution absorbing the refrigerant vapor from the absorption tank (AT) is transferred to the low temperature regeneration tank (GT-1) through the rare solution absorbent inlet pipe (GT-1L), the high temperature in the low temperature regeneration tank (GT-1) The absorbent is primarily heated by a heat exchange tube (GT-4L) through which high-temperature refrigerant vapor heated and separated from the regeneration tank (GT-2), and the heated absorbent is heated through the absorbent connection pipe (GT-2L). It is transferred to (GT-2). The absorbent first heated in the low temperature regeneration tank (GT-1) is absorbent and refrigerant through heat exchange with hot steam introduced through the boiler high temperature steam inlet pipe (GT-6L) in the high temperature regeneration tank (GT-2). Steam is separated. The concentrated liquid absorbent separated from the refrigerant vapor is transferred to the absorbent cooling tank (ACT) through the agricultural liquid absorbent conveying tube (GT-3L) and cooled, and the refrigerant vapor separated from the absorbent is a high temperature refrigerant vapor conveying tube (GT-4L). It is transferred to the low temperature regeneration tank (GT-1) through the primary heating of the absorbent and discharged to the outside.

The regeneration tank GT uses a low temperature regeneration tank GT-1 and a high temperature regeneration tank GT-2 to heat and separate the rare solution absorbent absorbing the refrigerant vapor, and then the concentrated solution absorbent is the absorbent cooling tank ACT. And the refrigerant vapor is discharged to the outside air.

5 is a system diagram of an absorbent cooling tank (A.C.T).

The structure of the absorbent cooling tank ACT is configured to circulate an inlet pipe (ACT-1L) for introducing the heated agricultural solution absorbent, a transfer pipe (ACT-2L) for transferring the cooled agricultural solution absorbent, and a refrigerant (ACT-W). Refrigerant circulation pump (ACT-P), refrigerant inlet pipe (ACT, -3L), absorption tank for absorbing evaporated refrigerant (ACT-AT), absorbent delivery pipe for transferring rare solution absorbent absorbing refrigerant vapor (ACT-P) 5L) and a vacuum pump (ACT-VP) to vacuum the inside of the absorbent cooling tank (ACT).

The action of the absorbent cooling tank (A.C.T) configured as above is as follows.

The action of the absorbent cooling tank (ACT) is the same as that of the evaporation tank (ET) and the absorption tank (AT), but the evaporation tank (ET) is the absorbent cooling tank (ACT), compared to cooling by heat exchange action with the cooling load. Acts to cool the heated agricultural solution absorbent, and in the action of the evaporation tank (ET) and the absorption tank (AT), the refrigerant vapor is transferred to the absorption tank (AT) by the refrigerant vapor in a forced circulation method. Is different in that the refrigerant vapor is transferred to the absorbent cooling tank (ACT) by the natural circulation method, and the inside of the evaporation tank (ET) is made into a high vacuum state of 6.5 mmHg, so that the refrigerant (ET-W) is evaporated at a low temperature of 5 ° C. The difference is that the cooling tank (ACT) is made into a 40 mmHg medium vacuum and evaporated at 40 ° C. to maintain the temperature of the absorbent at 40 ° C.

The main function of the absorbent cooling tank A.C.T is to cool the heated solution absorbent heated in the regeneration tank G.T to 40 ° C. and transfer it to the absorption tank A.T.

6 is a system diagram of a water tank (W.T).

The water tank (WT) consists of a cold water inlet pipe (WT-1L), a tap water inlet pipe (WT-2L), and a filter (WT-F) that filters the water stored in the water tank. ), Refrigerant transfer pipe (WT-3L) for transferring the water, which is a refrigerant, to the evaporation tank (ET), and water level detection sensors (WT-S1, WT-S2) and tap water inlet to detect the water level of the water tank (WT). It is composed of a solenoid valve (WT-SV / V) installed in the pipe (WT-2L) to adjust the amount of water stored and opened and closed according to the signals of the water level sensor (WT-S1, WT-S2).

Referring to the operation of the water tank (W.T) configured as described above are as follows.

The inlet pipe into which the refrigerant water is introduced is the tap water inlet pipe (WT-2L) where cold water inlet (WT-1L) and solenoid valve (WT-SV / V), which are always open, are installed to repeat water inlet and outlet. Consists of. The cold water inlet pipe (WT-1L) collects and draws in cold water generated by moisture in the air passing through the cooling fins of each indoor unit, and is continuously drawn in while cooling is performed. Explaining the action of controlling the amount of water, which is a refrigerant, if the amount of water (WT-W) sent to the evaporation tank (ET) is greater than the amount of water drawn through the cold-water inlet pipes (W, T-1L), the water tank ( The amount of water (WT-W) inside the WT is reduced so that the water level is detected by the lower water level sensor (WT-S1) and the solenoid valve (WT-SV / V) by the signal of the lower water level sensor (WT-S1). ) Is opened to draw water from the tap water. If the amount of water drawn in the cold water inlet pipe (WT-1L) and tap water inlet pipe (WT-2L) is greater than the water sent to the evaporation tank (ET), the amount of water in the water tank (WT) increases and the water level is The water level is detected by the upper water level sensor (WT-S2) and the solenoid valve (WT-SV / V) installed in the water inlet pipe (WT-2L) is closed by the signal of the sensor (WT-S2). The action of stopping the introduction of the refrigerant WT-W through the inlet pipe WT-2L is repeated, and the amount of the refrigerant WT-W is adjusted. A filter (W.T-F) is installed in the transfer pipe (W.T-3L) that transfers water, which is a refrigerant, to the evaporation tank (E.T), and filters all refrigerant that is sent to the evaporation tank (E.T). The absorbent circulation type cooling device according to the present invention is composed of a system for circulating the absorbent and consuming the refrigerant water, so that the refrigerant water must be continuously supplied during the cooling operation. If the water, which is a refrigerant, is supplied without being filtered, not only scale occurs in the evaporation tank (E.T-4) heat exchange tubes (E.T-4L, E.T-5L) but also the absorbent and contaminants react to reduce the absorbent efficiency. The filter uses a hollow fiber membrane filter having pores of 0.04 μm to filter fine contaminants and then transfer the refrigerant (W.T-W) to the evaporation tank (E.T).

7 is a schematic diagram of an absorbent circulation cooling device.

Water, which is a refrigerant, is stored in the water tank (WT) through the cold water inlet pipe (WT-1L) and the tap water inlet pipe (WT-2L), and the stored refrigerant is filtered through the filter (WT-F) to evaporate the tank (ET). When the refrigerant is injected into the evaporation tank ET in the high vacuum state (6.5 mmHg) by the vacuum pump AT-VP, the refrigerant evaporates at about 5 ° C. At this time, a low temperature brine (7 ° C.) required for cooling is obtained through heat exchange with a brine circulating through the evaporated refrigerant and the evaporation tank (ET) heat exchange tubes (ET-4L and ET-5L), and the refrigerant vapor is a refrigerant vapor. The circulating pump FT-P passes the evaporative refrigerant separator FT and is transferred to the absorption tank AT. When the absorbent of the concentrated solution (60 wt%) cooled in the absorbent cooling tank (A.C.T) is injected, the refrigerant vapor generated in the evaporation tank (E.T) is absorbed by the absorbent of the concentrated solution. Absorbent of rare solution whose concentration is lowered by absorption of refrigerant from absorption tank (AT) and its temperature is increased by absorption heat is transferred to regeneration tank (GT) by absorber circulation pump (AT-P). -1, GT-2) is separated into refrigerant vapor and concentrated absorbent by using heating energy. The absorbent of the regenerated agricultural liquid is transferred to the absorbent cooling tank (A.C.T) and cooled, and the hot refrigerant vapor separated from the absorbent is discharged to the outside air. The absorbent of the concentrated solution transferred to the absorbent cooling tank ACT is cooled by latent heat of evaporation of the refrigerant, and the absorbent of the concentrated concentrated solution in the absorbent cooling tank ACT is transferred to the absorption tank AT to absorb the refrigerant vapor. . Absorbent circulation cooling device as described above is a continuous cooling is carried out through the absorption of the absorbent, heat separation, cooling action circulation and low temperature evaporation of the refrigerant, absorption, heat evaporation, the outside air discharge.

The energy use efficiency of the existing absorption cooling device and the absorbent circulation cooling device is as follows.

Conventional absorption cooling device sprays coolant water into a high vacuum evaporator, water is evaporated at low temperature, and cooling is performed by using latent heat of evaporation. Is absorbed in. The absorbent of the concentrated solution heated and separated in the regenerator is moved to the absorber, and the absorbent of the rare solution having absorbed the refrigerant vapor from the absorber is continuously absorbed by the refrigerant vapor through a circulation action. If the absorbent absorbs the refrigerant in the absorber, the heat of absorption is generated. If the absorption heat is not removed through the heat exchange with the cooling water, the internal temperature of the absorption tank rises and the separation of the refrigerant vapor occurs, so that the refrigerant vapor cannot be absorbed. The cooling water must be circulated through the cooling device to ensure that the temperature of the absorbent solution is kept constant (40 ° C.). In the regenerator, the rare solution absorbent absorbing the liquid refrigerant from which the heat of absorption is removed by the cooling water is separated into a high temperature refrigerant vapor and a concentrated solution absorbent using thermal energy. The regenerated concentrate absorbent is transferred back to the absorber to be used for absorption of the refrigerant, and the hot refrigerant vapor is transferred to the condenser to condense through heat exchange with the cooling water. The condensed liquid refrigerant is transferred to the evaporator to serve as a refrigerant for cooling. Conventional absorption cooling devices have cooling water to remove the heat of absorption generated when the refrigerant vapor generated in the evaporator is absorbed by the absorbent, heating energy for separating the absorbent and the liquefied refrigerant in the regenerator, and high temperature refrigerant vapor separated from the absorbent. Since a cooling water is required to condense the heat, a heating device for separating the absorber and the refrigerant, and a cooling device for removing the heat of absorption and condensing the high temperature refrigerant vapor are needed. In order to operate the absorption cooling device as described above, a separate cooling device as well as a heating device must be installed to continuously supply the cooling water to the absorber and the condenser.

The process of consuming water, which is a refrigerant for cooling the absorbent circulation type air conditioner, and the process of circulating the absorbent agent are examined.

In the absorbent circulation type air conditioner, since the refrigerant evaporated at low temperature in the evaporation tank ET is absorbed by the cooled absorbent and transferred to the regeneration tank GT, a separate cooling device is not required in the absorption tank AT. Since the heat of absorption generated when absorbed in the heats up the absorbent, the regeneration tank GT can separate the absorbent and the refrigerant vapor only by heating energy minus the absorbed heat, thereby increasing energy use efficiency. And the absorbent cooling device consists of a circulation system that transfers the absorbent and the liquefied refrigerant from the regenerator to the heat condenser after cooling and condensing it to the evaporator. Is discharged to the outside air and the liquid refrigerant is composed of a system for filtering and supplying the cold water generated in the indoor unit can save the energy required to produce the cooling water required to condense the high temperature refrigerant vapor. Considering the amount of energy required for the refrigerant circulation cycle to perform cooling in the absorption air conditioner, the energy required per circulation cycle of the absorption air conditioner = cooling energy for removal of absorbing heat + cooling energy for absorbing cooling + absorbent absorbing liquid liquefied refrigerant. Heating energy for separation + cooling heat energy for condensation of heated steam refrigerant), and (required energy per circulation cycle of absorbent circulation cooling unit = heating energy for separating absorbent containing absorbent heat + cooling energy for cooling absorbent) Since the energy use efficiency of the absorbent cooling device and the absorbent circulation cooling device for obtaining the same cooling heat energy for cooling is examined, it can be seen that the energy use efficiency of the absorbent circulation cooling device is high.

Absorbent circulating cooling device according to the present invention is obtained from the cooling water from the coolant generated in the indoor unit, the refrigerant water is evaporated at low temperature in the evaporation tank to perform cooling by using the latent heat of evaporation, and then absorbed in the cooled agricultural solution absorber to the separation tank It is composed of a system that discharges high temperature refrigerant vapor separated by transfer by heat separation and discharges it to the outside, and cools only the agricultural liquid absorbent separated from the refrigerant vapor and transfers it to the absorption tank to remove heat of absorption or to condense high temperature refrigerant vapor. This eliminates the need for a separate cooling device for the installation, which not only saves money on the facility investment for installing the cooling device, but also reduces the operating costs for running the cooling device. In addition, the system is configured to heat-separate the absorbent heated by the heat of absorption generated when the refrigerant vapor is absorbed by the absorbent. Thus, the energy use efficiency is increased because the absorbent and the refrigerant vapor can be separated only by the heating energy minus the absorption heat.

Claims (1)

Cooling device that uses water (H2O) as refrigerant and lithium bromide (LiBr) as absorbent. Cold water storage tank with evaporator, evaporation tank, evaporative refrigerant separator, refrigerant vapor absorption tank, low temperature, It consists of a high temperature regeneration tank and an absorbent cooling tank, and uses the coolant water from the indoor unit as the refrigerant, and cools the load by using the latent heat of evaporation by evaporating the refrigerant as a low temperature using a high vacuum evaporation tank. Cooling is carried out by heat exchange with heat, and the evaporated refrigerant vapor is absorbed into the concentrated solution absorbent cooled using the absorption tank, and the rare solution absorbent absorbing the refrigerant vapor is absorbed and the refrigerant vapor is cooled using a low temperature and high temperature regeneration tank. The high temperature refrigerant vapor separated by heat separation is discharged to the outside, and the agricultural liquid absorbent separated from the refrigerant vapor is transferred to the absorbent cooling tank. Consists of a system that absorbs the refrigerant vapor by transporting it to the absorption tank after cooling, thereby eliminating the heat of absorption and condensing the refrigerant vapor after cooling Absorbent circulation cooling system characterized in that the discharge to the outside air without a process, and supplying a fresh refrigerant in the liquid state.